JPWO2007043375A1 - Conveying device and recording medium driving device - Google Patents

Abstract

In the disk device 100, when the large-diameter disk is clamped on the turntable 23, the guide lever 411 for guiding insertion / extraction of the large-diameter disk is moved to the left wall 10B side, and the periphery of the large-diameter disk and the guide lever 411 are moved. A push arm 416 that forms a predetermined clearance therebetween is provided. Thereby, when a large diameter disk is mounted in the turntable 23, rotation of a large diameter disk is not inhibited.

Description

  The present invention relates to a transport device for inserting and discharging a disk-shaped recording medium, and a recording medium driving device provided with the transport device.

  Conventionally, disk devices capable of storing disk-shaped recording media having different diameters inside the device are known. (For example, refer to Patent Document 1).

  The device described in Patent Document 1 is a disk reproducing device that transports a disk by a transfer roller and positions the disk above a turntable by a positioning mechanism. This positioning mechanism has left and right positioning levers that are pivotally supported by fulcrum pins and intersect each other, and fulcrum pins that engage engagement holes provided in these positioning levers, and are rotated by a solenoid. And a switching lever. Also, in the vicinity of the disc insertion opening of this disc reproducing apparatus, a center sensor, left and right sensors provided on the left and right of the center sensor, and outer sensors are provided, and the diameter of the disc inserted from the disc insertion opening by these sensors is set. Determine. When the insertion of the large-diameter disk is confirmed by the sensor, the switching lever is rotated to rotate the left and right positioning levers so that the positioning pin is at the most open position, and the insertion of the small-diameter disk is confirmed. Then, the structure which rotates the positioning lever on either side so that the positioning pin may be in the nearest position is taken.

Japanese Unexamined Patent Publication No. 02-118955 (refer to pages 3 to 5 and FIGS. 1 to 7)

  By the way, in the disk reproducing apparatus having a conventional configuration as described in Patent Document 1, after holding the disk with the left and right levers, the disk is clamped on the turntable. At this time, in a state where the disc is guided by the left and right levers, there is a problem that the rotation of the disc is hindered because the clearance is insufficient.

  An object of the present invention is to provide a transport device and a recording medium driving device that can hold a disk well without hindering the rotation of the disk.

  The transport device according to the present invention guides the recording medium to a position where a disk holding portion disposed inside the apparatus main body can hold the disk-shaped recording medium, and is movable in the contact / separation direction of the recording medium. And a guide movement control member configured to move the guide member in a direction away from the recording medium in a state where the recording medium is held by the disk holding unit.

  The recording medium driving apparatus of the present invention is provided with the above-described transport apparatus of the present invention, the disk holding section for holding the recording medium transported by the transport apparatus, and the disk holding section, and is moved in the vertical direction. Pedestal unit, information processing unit that performs at least one of writing of information to the recording medium held by the disk holding unit and reading of information from the recording medium, and a conveying device and a disk holding unit thereof The apparatus main body is provided with a pedestal part and an information processing part inside and provided with an insertion / extraction port for inserting / extracting the recording medium.

It is a top view which shows the inside of the apparatus main body of the disc apparatus which concerns on one Embodiment of this invention. FIG. 4 is an enlarged plan view of a push arm provided inside the disk device, and is an enlarged plan view of the push arm in a state where the guide lever and the push arm are not engaged. FIG. 3 is an enlarged plan view of a push arm provided inside a disk device, and is an enlarged plan view of the push arm in a state where a guide lever and a push arm are engaged. FIG. 3 is an enlarged plan view of a push arm provided inside the disk device, and is an enlarged plan view of the push arm in a state where the push arm is moved to the left wall side in the state of FIG. 2B. FIG. 3 is a plan view showing the inside of the main body of the disk device when the large-diameter disk is inserted and when the disk is completely discharged. It is a top view which shows the inside of the apparatus main body of the disc apparatus in the middle of conveyance of a large diameter disc. It is a top view which shows the inside of the apparatus main body of the disc apparatus at the time of completion of disc insertion of a large diameter disc. It is a top view which shows the inside of the apparatus main body of the disc apparatus in the state in which the large diameter disc was clamped by the turntable.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Optical disk 1A as a recording medium ... Large-diameter disk 10 as a recording medium ... Device main body 11 ... Slot 21 as an insertion / ejection slot ... Base part 23 ... Turntable 24 as a disk holding part ... Information processing part 41 ... Conveying device A disc guide mechanism 100 as a recording medium drive device 411 a guide lever 411 C constituting a guide member a rotation restricting pin 412 as an engaging portion a disc guide 416 constituting a guide member a guide movement control member Push arm 416A as a guide engaging member constituting the pin, a pin locking groove 416C as an engaging groove, a push arm biasing spring 424 as a biasing member, a slide stopper as a movement control member constituting the guide movement control member

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a plan view schematically showing the inside of a disk device according to an embodiment of the present invention. FIG. 2A is an enlarged plan view of the push arm provided inside the disk device, and is an enlarged plan view of the push arm in a state where the guide lever and the push arm are not engaged. FIG. 2B is a push diagram provided inside the disk device. FIG. 2C is an enlarged plan view of the arm, and is an enlarged plan view of the push arm in a state where the guide lever and the push arm are engaged. FIG. 2C is an enlarged plan view of the push arm provided inside the disk device. It is an enlarged plan view of the push arm in a state where the push arm has moved to the left wall side.

[Disk unit configuration]
In FIG. 1, reference numeral 100 denotes a disk device as a recording medium driving device according to an embodiment of the present invention. The disk device 100 is at least one surface of an optical disk 1 as a disk-shaped recording medium that is detachably mounted. A reading process, which is information processing for reading information recorded on a recording surface (not shown), and a recording process, which is information processing for recording various information on the recording surface, are performed. The disk device 100 is exemplified by a so-called thin slot-in type that is mounted on an electric device such as a portable personal computer. For example, the disk device 100 performs processing for recording and reproduction such as recording of a game machine or video data. A single unit such as a playback device may be used. Further, the disk device 100 can store a large-diameter disk 1A having a diameter of 12 cm and a small-diameter disk 1B having a diameter of 8 cm as the optical disk 1. The disk-shaped recording medium is not limited to the optical disk 1 and can be any disk-shaped recording medium such as a magnetic disk or a magneto-optical disk. The disk device 100 includes a substantially box-shaped device body 10 made of, for example, metal and having an internal space. 1, the lower side in FIG. 1 is the front 10A of the apparatus main body, the left side wall of the apparatus main body 10 in FIG. 1 is the left wall 10B, the right side wall of the apparatus main body 10 in FIG. The side opposite to the front surface 10A of the apparatus main body 10 is appropriately referred to as a back surface 10D.

  Inside the apparatus main body 10, there are provided a disk processing section 20 called a so-called traverse mechanism, a transport means 30 for transporting the optical disk 1, and a control circuit section (not shown) as a circuit board. . A slot 11 as an insertion / extraction opening for inserting / extracting the optical disk 1 is formed on the front surface 10A of the apparatus main body 10 so as to extend in the left-right direction in FIG.

  The disk processing unit 20 has a pedestal portion 21 that is formed in a substantially plate shape, for example, with a metal plate and is supported on the apparatus main body 10 so that one end thereof is swingable. The pedestal portion 21 is formed in a longitudinal direction from the front surface 10A side of the left wall 10B of the apparatus main body 10 toward the center position. The pedestal portion 21 has a longitudinal processing opening 21A cut out substantially in the center along the longitudinal direction. The disk rotation driving means 22 is disposed at one end of the processing opening 21 </ b> A of the pedestal 21, that is, at a substantially central position of the apparatus main body 10. The disk rotation driving means 22 includes a spindle motor (not shown) and a turntable 23 as a disk holding portion provided integrally with the output shaft of the spindle motor. The spindle motor is controllably connected to the control circuit unit and is driven by electric power supplied from the control circuit unit. The turntable 23 is a drive unit that is provided at a substantially central portion inside the apparatus main body 10 and that rotationally drives the optical disc 1.

  An information processing unit 24 is disposed on the pedestal unit 21. The information processing unit 24 is supported so as to be bridged between the pair of guide shafts 25, and is moved close to and away from the turntable 23 in the processing opening 21A by a moving mechanism (not shown). The information processing unit 24 includes a pickup having a light source (not shown), a pickup lens 24A for converging light from the light source, and an optical sensor (not shown) for detecting outgoing light reflected by the optical disc 1.

  The transport unit 30 includes a transport motor 31 that is disposed in the apparatus main body 10 and is controlled in operation by, for example, a control circuit unit, and a link mechanism unit 32 that is interlocked by driving the transport motor.

  The link mechanism portion 32 is provided inside the apparatus main body 10 on the left wall 10B side of the slot 11 and on the right wall 10C side of the slot 11 inside the apparatus main body 10. A disk diameter detection mechanism 42, a disk discharge mechanism 43 that discharges the optical disk 1 disposed on the turntable 23, and a first drive cam 44 and a second drive cam 45 that swing the pedestal 21 are provided. .

  The disc guide mechanism 41 includes a guide lever 411 as a guide member for guiding insertion / extraction of the optical disc 1, a disc guide 412 connected to the front surface 10A side of the guide lever 411, a bridge plate 413 as a protection plate, and a bridge An 8 cm arm 414 rotatably provided on the plate 413 and a push arm 416 as a guide engaging member are provided. The guide member of the present invention is constituted by a guide lever 411 and a disk guide 412, and the guide movement control member of the present invention is constituted by a push arm 416 and a slide stopper 424 as a movement control member described later. Yes. The guide lever 411, the disk guide 412, the push arm 416, and the slide stopper 424 constitute the conveying device of the present invention.

  The guide lever 411 is a rod-like member formed in a longitudinal shape in the disc insertion / ejection direction. A guide portion 411A made of synthetic resin that guides the movement of the optical disc 1 in the insertion / extraction direction is fixed to the side surface of the guide lever 411 on the inner side (side into which the optical disc 1 is inserted). The guide portion 411A is formed with a guide groove that is concave toward the left wall 10B side, and guides the periphery of the optical disc 1 in sliding contact with the guide groove. Further, the side surface of the guide lever 411 is formed such that the back surface 10D side following the guide portion 411A is curved inward, thereby restricting the movement of the optical disc 1. Further, the guide portion 411A is formed with a rotation restricting pin 411C as an engaging portion protruding to the bottom side. The rotation restricting pin 411C is provided on the disk guide 412 side of the guide lever 411, that is, on the front surface 10A side, and at a position where it does not interfere with the pedestal 21 when the guide lever 411 moves to a position corresponding to the small-diameter disk 1B. It has been.

  A guide pin 411B penetrating from the top surface side to the bottom surface side is fixed to the end portion of the guide lever 411 on the back surface 10D side. This guide pin 411B is locked to a bridge plate 413 and an 8 cm arm 414 described later. In addition, a disk guide 412 is rotatably connected to the front 10A side end of the guide lever 411.

  Further, a leaf spring 411D is provided at the end on the front surface 10A side of the guide lever 411 so as to face the left wall 10B. The leaf spring 411D biases the connecting portion between the guide lever 411 and the disk guide 412 inward when the guide lever 411 moves toward the left wall 10B. This prevents the connecting portion of the guide lever 411 and the disk guide 412 from being refracted outward.

  The disk guide 412 is formed in a longitudinal shape, and one end thereof is rotatably attached to the vicinity of the left wall 10B of the apparatus main body 10. Further, as described above, the other end of the disk guide 412 is rotatably connected to one end of the guide lever 411. As a result, the end portion on the front surface 10A side of the guide lever 411 can be rotated on an arc having the one end portion of the disk guide 412 as a rotation center and the length of the disk guide 412 as a diameter. Further, a flange portion 412A protruding inward is formed on the bottom surface side of the disc guide 412. When the optical disc 1 is inserted along the flange portion 412A, the peripheral portion of the optical disc 1 is slidably contacted. A sliding contact surface 412B is formed. Further, the connecting portion between the disc guide 412 and the guide lever 411 is an extruding portion 412C that pushes the periphery of the optical disc 1 toward the front surface 10A when the optical disc 1 is ejected.

  The bridge plate 413 is a plate-like member that is provided on the back surface 10D side of the apparatus main body 10 in the left-right direction. The bridge plate 413 is provided so as to cover the control circuit unit described above and protects the control circuit unit. A guide guide groove 415 serving as a guide guide portion is formed on the left wall 10B side of the bridge plate 413 from the corner portion on the back surface 10D side of the apparatus main body 10 toward the inner center position.

  The guide guide groove 415 includes an arc groove 415A serving as a first guide portion formed in a shape substantially parallel to the rotation trajectory of the connecting portion of the guide lever 411 and the disk guide 412 and the arc groove 415A. A linear groove 415B serving as a second guide portion extending substantially along the insertion / ejection direction of the optical disc 1 is formed continuously with the linear groove 415B, and the center of the apparatus main body 10 is formed at a predetermined angle with respect to the linear groove 415B. And an inclined groove 415C as a second guide portion inclined in the position direction. In the guide guide groove 415, a guide pin 411B that protrudes toward the bottom surface of the guide lever 411 is locked to guide the movement of the guide lever 411. Here, the straight groove 415B is set so that the length of the perpendicular line extending from the turntable 23 onto the extended line of the straight groove 415B is approximately the same as the radius of the small-diameter disk 1B.

  Further, an 8 cm arm 414 is pivotally supported on the right wall 10C side of the bridge plate 413 so as to be rotatable. Furthermore, an arc-shaped arm regulation groove 413A centering on the pivotal support position of the 8cm arm 414 is formed at the center portion of the bridge plate 413 and the right wall 10C side, and the rotational range of the 8cm arm 414 is regulated. .

  An assist arm 431 of a disc ejection mechanism 43 described later is pivotally supported on the right wall 10C side of the bridge plate 413, and an arc-shaped assist regulating groove 413B having a pivot center of the assist arm 431 is formed. Is formed. An eject arm 432 that meshes with the assist arm 431 is pivotally supported at the substantial center of the bridge plate 413 so as to be rotatable. Further, a control groove 413C that is long in the left-right direction is formed on the front surface 10A side of the bridge plate 413.

  As described above, the 8 cm arm 414 is pivotally supported on the right wall 10C side of the bridge plate 413 so as to be rotatable. Further, the 8 cm arm 414 includes an arm restricting pin 414A that protrudes to the bottom side, and the arm restricting pin 414A is engaged with the arm restricting groove 413A of the bridge plate 413. Further, a guide link groove 414B formed along the length of the 8 cm arm 414 is formed at the tip of the 8 cm arm 414. A guide pin 411B protruding to the top surface side of the guide lever 411 is engaged with the guide link groove 414B. An arm biasing spring 414C that biases the front end of the left wall 10B side of the 8cm arm 414 toward the front 10A side is provided in the vicinity of the pivot position of the 8cm arm 414. The arm biasing spring 414C always biases the 8 cm arm 414 counterclockwise. The 8 cm arm 414 biases the guide lever 411 so that the guide pin 411B returns to the initial state where the guide pin 411B is located at the tip of the inclined groove 415C of the guide guide groove 415.

  The push arm 416 is rotatably provided on the left wall 10B side of the bridge plate 413. As shown in FIG. 2A, the push arm 416 is formed in a longitudinal shape, and a pin locking groove 416A is formed as an engagement groove from one longitudinal end portion toward the shaft support position. When the guide pin 411B of the guide lever 411 moves in the circular arc groove 415A of the guide guide groove 415, the rotation restricting pin 411C formed in the guide portion 411A is disposed in the pin locking groove 416A as shown in FIG. 2B. Is inserted. When the guide lever 411 further moves to the left wall 10B side and the pin locking groove 416A is pushed by the rotation restricting pin 411C, the push arm 416 rotates to the left wall 10B side. In addition, a pressing piece 416B that protrudes downward is formed on the right wall 10C side of the push arm 416. When the optical disc 1 is clamped, that is, held by the turntable 23, the presser piece 416B comes into contact with a push stopper 424D of a slide stopper 424, which will be described later, and further rotates toward the left wall 10B as shown in FIG. 2C. Moved. As a result, the guide lever 411 is moved away from the periphery of the optical disc 1, and a predetermined clearance is formed between the guide portion 411 A of the guide lever 411 and the optical disc 1.

  Further, a push arm biasing spring 416 </ b> C as a biasing means is provided between the push arm 416 and the bridge plate 413. The push arm biasing spring 416C biases the push arm 416 inward, that is, the guide lever 411 in a state where the rotation restricting pin 411C is engaged with the pin locking groove 416A, toward the optical disc 1. When the slide stopper 424 is separated from the presser piece 416B, the push arm 416 is rotated inward. At this time, as described above, since the rotation restricting pin 411C is provided on the front surface 10A side of the guide lever 411, the front arm 10A side of the guide lever 411 is biased inward by the push arm biasing spring 416C. . Thereby, when the guide lever 411 is moved, the connecting portion between the guide lever 411 and the disc guide 412 does not protrude toward the left wall 10B, and the guide lever 411 can be moved normally.

  The disc diameter detection mechanism 42 cancels the movement restriction of the guide lever 411 of the disc guide mechanism 41 when the optical disc 1 inserted into the slot 11 is a large-diameter disc 1A, and when the optical disc 1 is a small-diameter disc 1B. The movement of the guide lever 411 is restricted.

  Specifically, the disc diameter detection mechanism 42 is connected to a load arm 421 serving as a detecting means whose one end abuts the optical disc 1 and whose other end is rotatable to the apparatus body 10, and the load arm 421. And an arm link mechanism 422 that releases the movement restriction of the guide lever 411 when the rotation angle of the load arm 421 is large and restricts the movement of the guide lever 411 when the rotation angle of the load arm 421 is small. .

  The load arm 421 is provided with a roller-like contact portion 421A that contacts the peripheral edge of the optical disc 1 at one end portion, and the other end portion is rotatably supported by the apparatus main body 10. The load arm 421 is formed of an elongated rectangular plate member, and a guide groove 421B is formed along the longitudinal direction thereof. Further, the load arm 421 is urged clockwise by urging means (not shown) so as to return to the initial position as shown in FIG.

  The arm link mechanism 422 includes a substantially flat link arm 423 provided with one end of a protrusion 423A guided in the guide groove 421B, and a substantially flat plate restricting means connected to the link arm 423 and one end. And a slide stopper 424.

  The load arm 421 and the link arm 423 are on the right wall 10C side in the apparatus main body 10 and are disposed in substantially the same plane as the plane on which the guide lever 411 and the disk guide 412 of the disk guide mechanism 41 are disposed. .

  The link arm 423 is rotatably supported with respect to the rotation shaft 423B fixed to the apparatus main body 10 on the other end side, and is engaged with the protrusion 423A across the rotation shaft 423B. 423C is formed on the link arm 423. Further, an urging member (not shown) is provided at an end portion of the link arm 423 where the engagement protrusion 423C is provided, and urges toward the right wall 10C side. As a result, the load arm 421 is biased inward, that is, clockwise.

  The slide stopper 424 is arranged on the back surface 10D side of the turntable 23 on the bottom surface side of the bridge plate 413 so as to be movable in the left-right direction in the figure. An inclined contact portion 424A that is inclined with respect to the insertion / extraction direction of 1 is formed. When the large-diameter disk 1A is inserted as the optical disk 1 and the load arm 421 is rotated, the link arm 423 is also rotated, and the engaging protrusion 423C is moved to the front surface 10A side, and is inclined to contact with the engaging protrusion 423C. Since the contact portion 424A is pushed, the slide stopper 424 slides to the right wall 10C side. The slide stopper 424 is provided with a restriction stopper 424B capable of closing a part of the arm restriction groove 413A of the bridge plate 413. When the load arm 421 rotates and the slide stopper 424 moves toward the right wall 10C as described above, the restriction stopper 424B opens the arm restriction groove 413A and the arm restriction pin 414A of the 8cm arm 414 is movable. It becomes. On the other hand, when the load arm 421 returns to the initial position and the slide stopper 424 returns to the initial position, the arm restricting groove 413A is closed and the arm restricting pin 414A cannot move. Thereby, the rotation of the guide lever 411 connected to the 8 cm arm 414 is also restricted. Thereby, the guide lever 411 can also move to the left wall 10B side.

  A cam interlocking groove 424C that can be connected to the second drive cam 45 is formed on the front surface 10A side of the slide stopper 424. As a result, when the second drive cam 45 moves, the slide stopper 424 also moves in the left-right direction. A push stopper 424D is provided on the left wall 10B side of the slide stopper 424. When the slide stopper 424 is moved to the left wall 10B side by the movement of the second drive cam 45, the push stopper 424D is brought into contact with the pressing piece 416B of the push arm 416 and restricts the rotation of the push arm 416.

  Further, an eject restricting window 424E is formed at an approximately center position of the slide stopper 424. The ejection restricting window 424E includes a large-diameter disc eject restricting groove 424E1 extending in the left-right direction and a small-diameter disc eject restricting groove 424E2. When the slide stopper 424 moves to the left wall 10B side by the movement of the second drive cam 45, the eject arm of the assist arm 431, which will be described later, is ejected into the ejection regulating groove 424E1 for large diameter discs and the ejection regulating groove 424E2 for small diameter discs. The restriction pin 431A is engaged to restrict the rotation of the assist arm 431. Further, these large-diameter disk ejection regulating grooves 424E1 and small-diameter disk ejection regulating grooves 424E2 are formed so that the end portions thereof are inclined in a direction away from the turntable 23, and the ejection regulating pins 431A are engaged with the inclined portions. By being combined, it becomes possible to secure a clearance between the eject arm 432 and the optical disc 1.

  The disc ejection mechanism 43 is a mechanism for ejecting the optical disc 1 by pushing it into the slot 11. The disc ejection mechanism 43 includes an assist arm 431 and an eject arm 432.

  As described above, the assist arm 431 includes the eject regulation pin 431A that is rotatably provided on the right wall 10C side of the bridge plate 413 and engages with the assist regulation groove 413B. Accordingly, the rotation range of the assist arm 431 is restricted in the assist restriction groove 413B. Further, as described above, the ejection regulating pin 431A is inserted through the ejection regulating window 424E, and the slide stopper 424 moves to engage with the large-diameter disk ejection regulating groove 424E1 or the small-diameter disk ejection regulating groove 424E2. As a result, the rotation of the assist arm 431 is restricted. Furthermore, a gear 431B is formed at one end of the assist arm 431 on the left wall 10B side. The assist arm 431 is urged counterclockwise by an urging member (not shown), that is, the gear 431B is directed toward the front surface 10A.

  The eject arm 432 is rotatably provided on the bridge plate 413 as described above, and the gear portion 432A located on the bottom surface side with the bridge plate 413 interposed therebetween, and the longitudinal arm located on the top surface side of the bridge plate 413 Part 432B. The gear portion 432A meshes with the gear 431B of the assist arm 431, and is urged clockwise by the urging force of the assist arm 431. By this urging force, the arm portion 432B is urged in the clockwise direction, that is, in the direction of pushing the optical disc 1 into the slot 11. In addition, a roller-shaped contact portion 432C that contacts the periphery of the optical disc 1 is provided at the tip of the arm portion 432B. Further, an arm control projection 432D is formed on the opposite side of the pivot portion of the eject arm 432 from the arm portion 432B. The arm control protrusion 432D contacts the side edge of the 8 cm arm 414 when the eject arm 432 rotates.

  The first drive cam 44 and the second drive cam 45 are respectively formed with engagement grooves, and engagement cam protrusions (not shown) formed on the two side surfaces of the pedestal 21 in these engagement grooves. Are engaged with each other. The first drive cam 44 and the second drive cam 45 are formed in a substantially long shape, and are advanced and retracted along the longitudinal direction by a motor and a gear mechanism (not shown). As a result, the pedestal 21 is swung so as to be close to and away from the recording surface of the optical disc 1 mounted on the turntable 23.

  The link arm 423 and the first drive cam 44 have a small amount of feeding of the optical disk 1 to be sent to the turntable 23 when the optical disk 1 is a large diameter disk 1A, and turn when the optical disk 1 is a small diameter disk 1B. A disc feed cam portion 51 is provided to increase the feed amount of the optical disc 1 sent to the table 23.

  The disc feeding cam 51 includes a protrusion 52 provided on the link arm 423 and a cam groove 53 that is engaged with the protrusion 52 and formed in the first drive cam 44.

  The cam groove 53 includes a first cam groove 53A for feeding the large diameter disk 1A, a second cam groove 53B for feeding the small diameter disk 1B, and one end of the first cam groove 53A and the second cam groove 53B. And a common cam groove 53 </ b> C joined together. The first cam groove 53A and the second cam groove 53B are formed to extend in the moving direction of the first drive cam 44, respectively.

  The second drive cam 45 is connected to the first drive cam 44, and moves forward and backward in the left-right direction in conjunction with the forward and backward movement of the first drive cam 44. Then, when a sensor (not shown) detects that the center of the optical disk 1 is located on the turntable 23, the first drive cam 44 moves to the back surface 10D side, and the second drive cam 45 moves to the left wall 10B side. Move to. Due to the movement of the second drive cam 45, the pedestal portion 21 comes close to the recording surface of the optical disk 1, and the optical disk 1 is clamped with respect to the turntable 23. In this state, the turntable 23 rotates and information is recorded and / or reproduced on the optical disc 1.

[Disk unit operation]
Next, the operation of the disk device 100 will be described with reference to FIGS. FIG. 3 is a plan view showing the inside of the main body of the disk device when the large-diameter disk 1A is inserted and when the large-diameter disk is completely ejected. FIG. 4 is a plan view showing the inside of the main body of the disk device during the conveyance of the large-diameter disk. FIG. 5 is a plan view showing the inside of the main body of the disk device when the disk insertion is completed when a large-diameter disk is inserted. FIG. 6 is a plan view showing the inside of the apparatus main body in a state where the clamping of the large-diameter disk to the turntable is completed.

(Inserting large-diameter discs)
The operation of the disk device when inserting a large-diameter disk 1A having a disk diameter of 12 cm into the disk device 100 in the initial state as shown in FIG. When the large-diameter disk 1A is inserted from the slot 11 of the disk device 100 in the initial state, the peripheral portion of the large-diameter disk 1A pushes the contact portion 421A of the load arm 421 toward the right wall 10C as shown in FIG. Move. As a result, the link arm 423 rotates counterclockwise, and the slide stopper 424 slides toward the right wall 10C. By this movement of the slide stopper 424, the restriction stopper 424B is disengaged from the arm restriction groove 413A of the bridge plate 413, and the control of the rotation range of the 8 cm arm 414 is released.

  When the large-diameter disk 1A is further pushed in this state, as shown in FIG. 4, the side edge of the large-diameter disk 1A comes into contact with the sliding contact surface 412B of the disk guide 412, and the disk guide 412 is moved to the left wall 10B side. Turn to. At this time, the guide lever 411 is also pushed into the back surface 10D side, and the guide pin 411B moves from the inclined groove 415C and the linear groove 415B of the guide guide groove 415 to the arc groove 415A. The guide pin 411B moves along the arc groove 415A toward the left wall 10B, so that the guide lever 411 moves toward the left wall 10B while maintaining a state substantially parallel to the disk insertion / ejection direction. The periphery of the large-diameter disc 1A is guided by the portion 411A. At this time, the rotation restricting pin 411C of the guide portion 411A is engaged with the pin locking groove 416A of the push arm 416, and the push arm 416 is also rotated to the left wall 10B side.

  Thereafter, when more than half of the large-diameter disk 1A is inserted into the apparatus main body 10, the load arm 421 is urged inward, that is, in the clockwise direction, and therefore, along the periphery of the large-diameter disk 1A. Moving. The load arm 421 pushes the large-diameter disk 1A from the front surface 10A to the rear surface 10D side by this urging force. Further, when more than half of the large-diameter disk 1A passes through the connecting portion between the guide lever 411 and the disk guide 412, the leaf spring 411D is biased inward so that the front 10A side protrudes inward. The guide lever 411 is inclined to guide the large-diameter disc 1A to the back.

  Then, as shown in FIG. 5, when the central portion of the large-diameter disk 1A is moved onto the turntable 23, the pedestal 21 is moved to the top surface by the movement of the first drive cam 44 and the second drive cam 45. The large-diameter disk 1A is clamped to the turntable 23 as shown in FIG. Specifically, when the large-diameter disk 1A is inserted, an insertion detection switch (not shown) is pushed, and the first drive cam 44 moves to the front 10A side. At this time, the protrusion 52 is inserted into the first cam groove 53A of the first drive cam 44, and the position of the load arm 421 is fixed in a state where a clearance is provided between the large-diameter disk 1A. Further, in conjunction with the movement of the first drive cam 44, the second drive cam 45 also moves to the left wall 10B side. Then, in conjunction with the first drive cam 44 and the second drive cam 45, the pedestal portion 21 moves to the top surface side, and the large-diameter disc 1A is clamped to the turntable 23.

  Further, as the second drive cam 45 moves to the left wall 10B side, the slide stopper 424 also moves to the left wall 10B side. As a result, as shown in FIG. 2C, the push stopper 424D pushes the presser piece 416B of the push arm 416 toward the left wall 10B and restricts the movement. Thereby, the guide lever 411 in which the rotation restricting pin 411C is locked in the pin locking groove 416A is pressed to the left wall 10B side, and a clearance of a predetermined dimension is provided between the large diameter disc 1A.

  Further, by the movement of the slide stopper 424, the eject restricting pin 431A of the assist arm 431 is engaged with the large diameter disc eject restricting groove 424E1, and the abutting portion 432C of the eject arm 432 has a predetermined size between the large diameter disc 1A. Movement is restricted with the clearance provided.

(Discharge of large diameter disc)
Next, the operation for discharging the large-diameter disk 1A will be described. For example, when the operator presses the eject button, for example, the first drive cam 44 first moves to the back surface 10D side, and in conjunction with the first drive cam 44, the second drive cam 45 also moves to the right wall 10C side. Moving. Thereby, the base part 21 moves to the bottom side, and the clamp state of the large-diameter disk 1A is released. When the second drive cam 45 moves to the right wall 10C side, the slide stopper 424 also moves to the right wall 10C side, and when the push stopper 424D moves away from the push arm 416, the push arm 416 has a push arm. The biasing force of the biasing spring 416C rotates inward (right wall 10C side). As a result, the guide portion 411A of the guide lever 411 contacts the peripheral edge of the large-diameter disk 1A and holds the optical disk 1. In addition, the movement restriction of the eject arm 432 and the load arm 421 is similarly released by the movement of the slide stopper 424 toward the right wall 10C, and the peripheral edge of the large-diameter disk 1A is held. Then, the large-diameter disk 1A is pushed toward the front surface 10A by the urging force of the eject arm 432.

  When the left end edge of the large-diameter disk 1A is ejected to the front 10A side from the connecting portion of the guide lever 411 and the disk guide 412, the pushing portion 412C of the disk guide 412 moves the peripheral edge of the large-diameter disk 1A to the front 10A side. Extrude. That is, when the guide pin 411B is pushed to the front 10A side by the 8 cm arm 414 and passes through the linear groove 415B, the guide lever 411 is also pushed to the front 10A side. At this time, the connecting portion of the guide lever 411 and the disc guide 412 protrudes inward along the rotation arc of the disc guide 412 and the guide lever 411 is inclined. Thereby, the front 10A side end part of the guide lever 411 can extrude the peripheral part of the large diameter disc 1A. Further, when the guide pin 411B passes through the inclined groove 415C, the guide lever 411 moves so as to protrude further inward. Thereby, discharging of the large-diameter disk 1A is further promoted.

  Further, when the right end portion of the large-diameter disk 1A is ejected to the front surface 10A side with respect to the contact portion 421A of the load arm 421, the first drive cam 44 further moves to the rear surface 10D side, so that the projection 52 is formed. Engaged with the common cam groove 53C, the load arm 421 rotates inward. By rotating the load arm 421, the periphery of the large-diameter disk 1A is pushed toward the front surface 10A, and the large-diameter disk 1A is ejected.

[Effects of disk unit]
As described above, in the disk device 100 according to the above-described embodiment, when the large-diameter disk 1A is clamped to the turntable 23, the guide lever 411 that guides insertion / extraction of the large-diameter disk 1A is moved to the left wall 10B side. In addition, a push arm 416 that forms a predetermined clearance between the peripheral edge of the large-diameter disk 1A and the guide lever 411 is provided. For this reason, when the large-diameter disk 1A is placed on the turntable 23, the guide lever 411 does not hinder the rotation of the large-diameter disk 1A. Therefore, the large-diameter disk 1A can be clamped satisfactorily, and reading errors can be avoided due to rotation inhibition.

  The push arm 416 is biased by the push arm biasing spring 416C so as to rotate inward, that is, the side where the large-diameter disk 1A is disposed. For this reason, the guide lever 411 is always moved by the push arm 416 when the large-diameter disc 1A is not clamped by the turntable 23 and the rotation restricting pin 411C is engaged with the pin locking groove 416A. It is urged inward. Therefore, the large-diameter disk 1A can be reliably held by the guide lever 411, and the large-diameter disk 1A can be well guided by the guide portion 411A.

  One end of the push arm 416 is rotatably provided on the bridge plate 413, and the other end is biased inward by a push arm biasing spring 416C. For this reason, the movement range of the push arm 416 can be reduced, and the movement of the guide lever 411 can be restricted with a simple configuration.

  The push arm 416 further includes a pin locking groove 416A that engages with a rotation restricting pin 411C provided on the guide lever 411. When the guide lever 411 moves to the left wall 10B side, the rotation restricting pin 411C The movement of the guide lever 411 is restricted by being engaged with the pin locking groove 416A. For this reason, the push arm 416 can restrict the movement of the guide lever 411 with a simple configuration in which the rotation restricting pin 411C of the guide lever 411 is engaged.

  Further, in the disc apparatus 100 of the type in which the guide lever 411 moves along the arc groove 415A substantially parallel to the insertion / ejection direction of the optical disc 1 as in the present embodiment, one end as described above is rotatably attached. A push arm 416 in which a pin locking groove 416A is formed from the other end toward the rotation center is used. For this reason, the push arm 416 can restrict the movement of the guide lever 411 with a minimum movement by engaging the rotation restricting pin 411C of the guide lever 411 with the pin locking groove 416A and rotating. . Therefore, the size of the push arm 416 can be reduced, and the configuration is simplified. Therefore, it is possible to contribute by making the disk device 100 smaller and thinner.

  The rotation restricting pin 411C is provided on the front surface 10A side of the guide lever 411. For this reason, it is possible to prevent the connection portion between the guide lever 411 and the disk guide 412 from rotating outward, that is, toward the left wall 10B.

  The rotation restricting pin 411C is provided at a position where the guide lever 411 does not interfere with the pedestal portion 21 when the guide lever 411 guides the small-diameter disk 1B. That is, even when the pedestal 21 moves upward and the small-diameter disk 1B is clamped to the turntable 23, the rotation restricting pin 411C does not contact the pedestal 21. For this reason, a clamping mistake due to contact between the base portion 21 and the rotation restricting pin 411C, an error in information processing of the small-diameter disk 1B, and the like do not occur.

[Modification of Embodiment]
Note that the present invention is not limited to the above-described embodiment, and includes the following modifications as long as the object of the present invention can be achieved.

  That is, in the above-described embodiment, the rotation restricting pin 411C that engages with the pin locking groove 416A of the push arm 416 protrudes toward the bottom surface at the front 10A side of the guide lever 411 and at a position that does not interfere with the pedestal portion 21. However, the present invention is not limited to this. For example, if the rotation restricting pin 411C is formed so as to protrude from the top surface side of the guide lever 411, the rotation restricting pin 411C can be further formed on the front surface 10A side because it does not contact the pedestal portion 21. In this case, the push arm 416 may be provided on the top surface corresponding to the rotation restricting pin 411C.

  Further, although the rotation restricting pin 411C is provided on the front surface 10A side of the guide lever 411, it may be configured to be provided on the back surface 10D side. In this case, a rotation restricting member is provided so that the connecting portion of the guide lever 411 and the disk guide 412 does not rotate outward, or the connecting portion is prevented from separately protruding and rotating outward. An urging member can be provided.

  Further, an example in which the rotation restricting pin 411C of the guide lever 411 is engaged with the pin locking groove 416A provided in the push arm 416 has been shown. For example, a locking pin is provided in the push arm 416 and this pin is provided in the guide lever 411. It is good also as a structure which forms the groove part engaged with. In such a configuration, since there is no problem such as interference between the pin and the pedestal, the push arm 416 can be further attached to the front 10A side. Therefore, it is possible to prevent the connecting portion of the guide lever 411 and the disk guide 412 from rotating more reliably.

  In addition, although the push arm 416 has a configuration in which one end is pivotally supported by the bridge plate 413 and the push arm biasing spring 416C is provided at the other end, the configuration is not limited thereto. For example, it may be a member that moves the push arm 416 in a direction intersecting the moving direction of the guide lever 411. For example, it is a slide member that translates in the same direction with respect to the left-right moving direction of the guide lever 411. Also good. Even with such a member, the guide lever 411 can be moved to the left wall 10B side by moving to the left wall 10B side in a state where the rotation restricting pin 411C of the guide lever 411 is engaged.

  Moreover, although the slide stopper 424 was illustrated as a movement control member, it is not restricted to this. For example, a pedestal interlocking member that is connected to the pedestal 21 and moves the push arm 416 to the left wall 10B side in accordance with the vertical movement of the pedestal 21 may be provided.

  In addition, the specific structure for carrying out the present invention can be appropriately changed to another structure or the like within a range in which the object of the present invention can be achieved.

[Effect of the embodiment]
In the disk device 100 according to the above-described embodiment, when the large-diameter disk 1A is clamped to the turntable 23, the guide lever 411 that guides insertion / extraction of the large-diameter disk 1A is moved to the left wall 10B side. A push arm 416 that forms a predetermined clearance between the peripheral edge of 1A and the guide lever 411 is provided. For this reason, when the large-diameter disk 1A is placed on the turntable 23, the guide lever 411 does not hinder the rotation of the large-diameter disk 1A. Therefore, the large-diameter disk 1A can be clamped satisfactorily, and reading errors can be avoided due to rotation inhibition.

  INDUSTRIAL APPLICABILITY The present invention can be used for a conveyance device that inserts and discharges a disk-shaped recording medium, and a recording medium driving device provided with the conveyance device.

[0002]
[0006]
An object of the present invention is to provide a transport device and a recording medium driving device that can hold a disk well without hindering the rotation of the disk.
Means for Solving the Problems [0007]
The transport device according to the present invention guides the recording medium to a position where a disk holding portion disposed inside the apparatus main body can hold the disk-shaped recording medium, and is movable in the contact / separation direction of the recording medium. And a guide movement control member that moves the guide member in a direction away from the recording medium in a state where the recording medium is held by the disk holding portion, and the guide movement control member includes the guide A guide engaging member engageable with the member; and the guide engaging member is moved in a state in which the guide engaging member is engaged with the guide engaging member and the recording medium is held by the disc holding portion. An engaging portion that includes a movement restricting member that restricts, and the guide member is formed in a longitudinal shape substantially parallel to the conveyance direction of the recording medium, and is engageable with the guide engaging member A guide lever having one end portion rotatably provided on the apparatus main body and a other end rotatably connected to one end portion of the guide lever. Is provided with an engaging groove in which the engaging portion can be engaged by movement of the guide lever.
[0008]
The recording medium driving apparatus of the present invention is provided with the above-described transport apparatus of the present invention, the disk holding section for holding the recording medium transported by the transport apparatus, and the disk holding section, and is moved in the vertical direction. Pedestal unit, information processing unit that performs at least one of writing of information to the recording medium held by the disk holding unit and reading of information from the recording medium, and a conveying device and a disk holding unit thereof The apparatus main body is provided with a pedestal part and an information processing part inside and provided with an insertion / extraction port for inserting / extracting the recording medium.
BRIEF DESCRIPTION OF THE DRAWINGS [0009]
FIG. 1 is a plan view showing the inside of an apparatus main body of a disk apparatus according to an embodiment of the present invention.
FIG. 2A is an enlarged plan view of the push arm provided inside the disk device, and is an enlarged plan view of the push arm in a state where the guide lever and the push arm are not engaged.
FIG. 2B is an enlarged plan view of the push arm provided inside the disk device, and is an enlarged plan view of the push arm in a state where the guide lever and the push arm are engaged.
2C is an enlarged plan view of the push arm provided inside the disk device, and is an enlarged plan view of the push arm in a state where the push arm is moved to the left wall side in the state of FIG. 2B.
FIG. 3 is a plan view showing the inside of the main body of the disk device at the initial stage of disk insertion of the large-diameter disk and when the disk is completely ejected.

Claims (8)

A guide member that guides the recording medium to a position where a disk holding unit disposed inside the apparatus main body can hold the disk-shaped recording medium, and is movable in the contact / separation direction of the recording medium;
A guide movement control member that moves the guide member in a direction away from the recording medium in a state where the recording medium is held by the disc holding unit;
A conveying apparatus characterized by comprising: It is a conveying apparatus of Claim 1, Comprising:
The conveyance device characterized in that the guide movement control member urges the guide member in a direction approaching the recording medium in a state where the recording medium is not held by the disk holding unit. It is a conveying apparatus of Claim 1 or Claim 2, Comprising:
The guide movement control member includes: a guide engaging member that can be engaged with the guide member; and the guide engaging member that is engaged with the guide engaging member and the recording medium being held by the disc holding portion. A transfer device comprising a movement restricting member for restricting movement of the guide engaging member. It is a conveyance apparatus of Claim 3, Comprising:
One end of the guide engaging member is rotatably provided in the apparatus main body, and a biasing member that biases the other end of the guide engaging member in a direction approaching the recording medium is provided. apparatus. It is a conveying apparatus of Claim 3 or Claim 4, Comprising:
The guide member is formed in a longitudinal shape substantially parallel to the conveyance direction of the recording medium, and a guide lever having an engaging portion that can be engaged with the guide engaging member, and one end portion pivoting on the apparatus main body. A disc guide that is provided so that the other end is rotatably connected to one end of the guide lever,
The conveying device, wherein the guide engaging member includes an engaging groove in which the engaging portion can be engaged by movement of the guide lever. It is a conveyance apparatus of Claim 5, Comprising:
The conveying device, wherein the engaging portion is provided on a connecting portion side of the guide lever and the disc guide. It is a conveyance apparatus of Claim 5, Comprising:
The engaging device is provided at a position that does not interfere with a pedestal on which the disc holding unit is provided in a state where the recording medium is held by the disc holding unit. A transport apparatus according to any one of claims 1 to 7,
The disk holding unit for holding the recording medium conveyed by the conveying device;
The disk holding portion is provided, and a pedestal portion movable in the vertical direction,
An information processing unit that performs at least one of writing of information to the recording medium held by the disc holding unit and reading of information from the recording medium;
The apparatus main body is provided with an insertion / extraction port for accommodating the conveying device, the disk holding unit, the pedestal unit, and the information processing unit therein, and for inserting / extracting the recording medium,
A recording medium driving apparatus comprising:

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